This invention relates in general to seal assemblies and in particular to a seal assembly for a plug that can be used to seal and test a well component.
A typical subsea wellhead assembly has a high pressure wellhead housing supported in a lower pressure wellhead housing and secured to casing that extends into the well. One or more casing hangers land in the wellhead housing, the casing hanger being located at the upper end of a string of casing that extends into the well to a deeper depth. A string of tubing extends through the casing for production fluids.
Well components are pressure tested after installation to detect leaks. A plug comprising a seal can be used to pressure test the well components. The plug can be landed at a tubular well component and the seal can be set to establish a seal at the well component. The portion of the well below the plug can then be hydraulically pressurized from a remotely operated vehicle (“ROV”) or via a hydraulic line from the surface to thereby pressure test the well components below the plug. The plug is usually removed after testing of the well component but can remain in place until a later time when other components, such as a tree, are installed. The pressure tested well component can be, for example, a wellhead housing, a tree, a gooseneck connection, or a pigging head. Further, the integrity of riser components can also be pressure tested by setting the plug in the riser. One example of riser component to be pressure tested would be a gooseneck connection at the top of a freestanding riser.
The plug's seal is typically set using the plug's own weight. This weight-activated plug setting approach is adequate to set seals with a setting force of a few hundred pounds. However, plug seals used to conduct high pressure tests of well components can require setting forces of approximately 2,000 psi, depending on size. The weight of the plug is thus insufficient to set these high pressure seals that can be rated for test pressures of up to 15,000 psi.
One approach attempting to address the shortcomings of weight activated setting calls for the use of a tool or an ROV to set plugs with seals having a higher setting force. The tool or ROV can screw in a plug having a seal with up to a 5000 psi setting force. However, the force applied by an ROV may also be insufficient to set a seal assembly for a plug rated for test pressures of 15,000 psi or more.
A need exists for a technique that addresses the seal setting problems described above. In particular a need exists for a technique to set a high pressure plug seal for testing well components. The following technique may solve these problems.
In an embodiment of the present technique, a self-inserting seal assembly is provided that can allow high pressure seals in plugs to be set in well and riser components. The well and riser components can then be pressure tested to detect leaks after installation. The self-inserting seal assembly can be ROV installable and retrievable.
In the illustrated embodiment, the self-inserting seal assembly has a hydraulically actuated piston rod inside an inner housing having a seal portion, an outer housing, and landing support. The assembly comprises an outer set of dogs and an inner set of dogs. The outer set of dogs is initially recessed in the outer housing and in contact with the seal portion. As an actuator connected to the lower end of the piston rod is forced downward, the outer dogs move outward to engage a mating profile formed on the well component. This locking engagement between the outer dogs and the mating profile of the well component provides a reaction point that allows the seal located at the bottom part of the seal portion to come into sealing engagement with the well component. Continued downward movement of the actuator forces an inner set of dogs to lockingly engage with a set of grooves formed on the interior of the outer housing to hold the seal portion and thereby the seal in place. The well or riser components can then be pressure tested via a port in the assembly.
In the illustrated embodiment, upon completion of testing, the self-inserting seal assembly can be unlocked by the ROV by retracting the inner dogs and pulling the seal portion up to unset the seal. Continued movement upward of the seal portion causes the outer dogs to retract and allows the retrieval of the assembly by the ROV.
The combination of reaction points provided by the locking mechanisms of the dogs with the mating profiles, and the hydraulically actuated piston rod, provides the setting force needed to set the high pressure seals used to test well and riser components.
Referring to
In this example, the well component 10 comprises a bore 11 having a mating profile 12 formed on the inner diameter. The mating profile 12 can be comprised of annular grooves that interrupt the profile of the inner diameter. Bore 11 has an upper portion 11a and an annular seal surface 11b directly below. Seal surface 11b is smaller in diameter than bore upper portion 11a. A lower portion 11c is directly below seal surface 11b and can have a smaller inner diameter than the inner diameter of the seal surface 11b. However, it is not a requirement that the inner diameter of the lower portion 11c be smaller that that of the seal surface 11b.
Well component 10 provides a shoulder to land a self-inserting seal assembly 20. The self-inserting seal assembly 20 comprises an external flange or landing support 22 that rests on the shoulder of the well component 10.
The self-inserting seal assembly 20 further comprises a cylindrical outer housing 24 having a cylindrical inner surface 26 that, like the well component, has an annular grooved mating profile 28. A set of outer dogs 46 can move outward to engage the grooved mating profile 28 during installation to lock the outer housing 24 to the well component 10. However, other devices may be used to lock the outer housing 24 to the well component. For example, a split ring may be used to lock the outer housing 24 to the well component. The split-ring may be biased to expand outward to engage the mating profile 28. Landing support 22 joins and extends radially outward from outer housing 24. A seal portion 40 carrying a seal 44 on its bottom portion is partially housed within the outer housing 24 and is in axial sliding engagement with the outer housing 24. Seal portion 40 has an outer diameter equal or larger than the diameter of outer housing 24 below landing support 22. The seals 44 can be of the Polypak or S-Seal type. The seal portion 40 is integrally connected to an inner housing 42 and defines an opening in which a set of transfer pins or rods 50 sit. Recesses 45 formed on the inner housing 42 serve to initially house the interior ends of the outer dogs 46 before the outer dogs 46 extend during installation. The transfer rods 50 can move radially to force the inner dogs 52 outward in response to axial movement of an actuator 48 within a cavity 49 in the seal portion 40 and the inner housing 42. Recesses 47 formed on the actuator 48 serve to hold the interior ends of the transfer rods 50 when retracted. Transfer rods 50 and inner dogs 52 serve as a locking member to lock inner housing 42 in a lower portion in outer housing 24. A plurality of fasteners 54 fasten a top plate to the inner housing 42. A piston rod 60 that can extend and retract from a double-action hydraulic cylinder 70 connects to the actuator 48 to move it upwards and downwards relative to the seal portion 40 and the inner housing 42.
The sequence of the installation operation is shown in
Referring to
Referring to
Referring to
Once the seal 44 is set, the well component can be pressure tested. A pressure testing port 62 and flexible line 64 (schematically shown by dotted lines) will traverse the seal portion 40 and the outer housing 24 to place the portion of the well below the seal assembly 20 in communication with a pressure source (not shown) on the ROV or at the surface. Test port 62 does not pass through rods 50 or fasteners 54. In this way, the space below the seal assembly can be pressurized up to 15,000 psi to thereby pressure test the well component 10. Alternatively, the seal assembly can set a seal in a riser component to provide pressure testing for the riser component. The riser component is another type of well component.
Referring to
The piston rod 60 will continue to pull the actuator 48 up, forcing it up against the plates located fastened to the top of the inner housing 42. The upward force on the actuator 48 is thus transferred to the fastened plate, causing the seal portion 40 to move upward to unset the seals 44. As the recess 45 (
While the invention has been shown in only one of its forms, it should be apparent to those skilled in the art that it is not so limited but is susceptible to various changes without departing from the scope of the invention.
Number | Name | Date | Kind |
---|---|---|---|
3087547 | Raulins et al. | Apr 1963 | A |
4273372 | Sheshtawy | Jun 1981 | A |
4634152 | Pettit | Jan 1987 | A |
4911244 | Hynes | Mar 1990 | A |
6202745 | Reimert et al. | Mar 2001 | B1 |
6978839 | Fenton et al. | Dec 2005 | B2 |
20090194291 | Fesi et al. | Aug 2009 | A1 |
20090277645 | Pallini et al. | Nov 2009 | A1 |
Number | Date | Country | |
---|---|---|---|
20100294486 A1 | Nov 2010 | US |